/*
    SPDX-FileCopyrightText: 2005 Casper Boemann <cbr@boemann.dk>
    SPDX-FileCopyrightText: 2009 Dmitry Kazakov <dimula73@gmail.com>
    SPDX-FileCopyrightText: 2010 Cyrille Berger <cberger@cberger.net>

    SPDX-License-Identifier: GPL-3.0-only OR LicenseRef-KDE-Accepted-GPL
*/

#include "kis_cubic_curve.h"

#include <QPointF>
#include <QSharedData>
#include <QStringList>

template <typename T> class KisTridiagonalSystem
{
    /*
     * e.g.
     *      |b0 c0  0   0   0| |x0| |f0|
     *      |a0 b1 c1   0   0| |x1| |f1|
     *      |0  a1 b2  c2   0|*|x2|=|f2|
     *      |0   0 a2  b3  c3| |x3| |f3|
     *      |0   0  0  a3  b4| |x4| |f4|
     */

public:
    /**
     * @return - vector that is storing x[]
     */
    static QVector<T> calculate(QList<T> &a, QList<T> &b, QList<T> &c, QList<T> &f)
    {
        QVector<T> x;
        QVector<T> alpha;
        QVector<T> beta;

        int i;
        int size = b.size();

        Q_ASSERT(a.size() == size - 1 && c.size() == size - 1 && f.size() == size);

        x.resize(size);

        /**
         * Check for special case when
         * order of the matrix is equal to 1
         */
        if (size == 1) {
            x[0] = f[0] / b[0];
            return x;
        }

        /**
         * Common case
         */

        alpha.resize(size);
        beta.resize(size);

        alpha[1] = -c[0] / b[0];
        beta[1] = f[0] / b[0];

        for (i = 1; i < size - 1; ++i) {
            alpha[i + 1] = -c[i] / (a[i - 1] * alpha[i] + b[i]);

            beta[i + 1] = (f[i] - a[i - 1] * beta[i]) / (a[i - 1] * alpha[i] + b[i]);
        }

        x.last() = (f.last() - a.last() * beta.last()) / (b.last() + a.last() * alpha.last());

        for (i = size - 2; i >= 0; --i) {
            x[i] = alpha[i + 1] * x[i + 1] + beta[i + 1];
        }

        return x;
    }
};

template <typename T_point, typename T> class KisCubicSpline
{
    /**
     *  s[i](x)=a[i] +
     *          b[i] * (x-x[i]) +
     *    1/2 * c[i] * (x-x[i])^2 +
     *    1/6 * d[i] * (x-x[i])^3
     *
     *  h[i]=x[i+1]-x[i]
     *
     */

protected:
    QList<T> m_a;
    QVector<T> m_b;
    QVector<T> m_c;
    QVector<T> m_d;

    QVector<T> m_h;
    T m_begin;
    T m_end;
    int m_intervals{0};

public:
    KisCubicSpline()
        : m_begin(0)
        , m_end(0)

    {
    }
    explicit KisCubicSpline(const QList<T_point> &a)
        : m_begin(0)
        , m_end(0)
    {
        createSpline(a);
    }

    /**
     * Create new spline and precalculate some values
     * for future
     *
     * @a - base points of the spline
     */
    void createSpline(const QList<T_point> &a)
    {
        int intervals = m_intervals = a.size() - 1;
        int i;
        m_begin = a.constFirst().x();
        m_end = a.last().x();

        m_a.clear();
        m_b.resize(intervals);
        m_c.clear();
        m_d.resize(intervals);
        m_h.resize(intervals);

        for (i = 0; i < intervals; ++i) {
            m_h[i] = a[i + 1].x() - a[i].x();
            m_a.append(a[i].y());
        }
        m_a.append(a.last().y());

        QList<T> tri_b;
        QList<T> tri_f;
        QList<T> tri_a; /* equals to @tri_c */

        for (i = 0; i < intervals - 1; ++i) {
            tri_b.append(2. * (m_h[i] + m_h[i + 1]));

            tri_f.append(6. * ((m_a[i + 2] - m_a[i + 1]) / m_h[i + 1] - (m_a[i + 1] - m_a[i]) / m_h[i]));
        }
        for (i = 1; i < intervals - 1; ++i) {
            tri_a.append(m_h[i]);
        }

        if (intervals > 1) {
            KisTridiagonalSystem<T> tridia;
            m_c = tridia.calculate(tri_a, tri_b, tri_a, tri_f);
        }
        m_c.prepend(0);
        m_c.append(0);

        for (i = 0; i < intervals; ++i) {
            m_d[i] = (m_c[i + 1] - m_c[i]) / m_h[i];
        }

        for (i = 0; i < intervals; ++i) {
            m_b[i] = -0.5 * (m_c[i] * m_h[i]) - (1 / 6.0) * (m_d[i] * m_h[i] * m_h[i]) + (m_a[i + 1] - m_a[i]) / m_h[i];
        }
    }

    /**
     * @brief Get value of precalculated spline in the point at \@x
     */
    T getValue(T x) const
    {
        T x0;
        int i = findRegion(x, x0);
        /* TODO: check for asm equivalent */
        return m_a[i] + m_b[i] * (x - x0) + 0.5 * m_c[i] * (x - x0) * (x - x0) + (1 / 6.0) * m_d[i] * (x - x0) * (x - x0) * (x - x0);
    }

    T begin() const { return m_begin; }

    T end() const { return m_end; }

protected:
    /**
     * @brief findRegion - Searches for the region containing \@x
     * @param x - out parameter, containing beginning of the region
     * @return - index of the region
     */
    int findRegion(T x, T &x0) const
    {
        int i;
        x0 = m_begin;
        for (i = 0; i < m_intervals; ++i) {
            if (x >= x0 && x < x0 + m_h[i]) {
                return i;
            }
            x0 += m_h[i];
        }
        if (x >= x0) {
            x0 -= m_h[m_intervals - 1];
            return m_intervals - 1;
        }

        qDebug("X value: %f\n", x);
        qDebug("m_begin: %f\n", m_begin);
        qDebug("m_end  : %f\n", m_end);
        Q_ASSERT_X(0, "findRegion", "X value is outside regions");
        /* **never reached** */
        return -1;
    }
};

static bool pointLessThan(const QPointF &a, const QPointF &b)
{
    return a.x() < b.x();
}

struct KisCubicCurve::Data : public QSharedData
{
    Data() { init(); }
    Data(const Data &data)
        : QSharedData()
    {
        init();
        points = data.points;
    }
    void init()
    {
        validSpline = false;
        validU16Transfer = false;
        validFTransfer = false;
    }
    ~Data() = default;
    mutable KisCubicSpline<QPointF, qreal> spline;
    QList<QPointF> points;
    mutable bool validSpline;
    mutable QVector<quint16> u16Transfer;
    mutable bool validU16Transfer;
    mutable QVector<qreal> fTransfer;
    mutable bool validFTransfer;
    void updateSpline();
    void keepSorted();
    qreal value(qreal x);
    void invalidate();
    template <typename _T_, typename _T2_> void updateTransfer(QVector<_T_> *transfer, bool &valid, _T2_ min, _T2_ max, int size);
};

void KisCubicCurve::Data::updateSpline()
{
    if (validSpline) {
        return;
    }
    validSpline = true;
    spline.createSpline(points);
}

void KisCubicCurve::Data::invalidate()
{
    validSpline = false;
    validFTransfer = false;
    validU16Transfer = false;
}

void KisCubicCurve::Data::keepSorted()
{
    std::sort(points.begin(), points.end(), pointLessThan);
}

qreal KisCubicCurve::Data::value(qreal x)
{
    updateSpline();
    /* Automatically extend non-existing parts of the curve
     * (e.g. before the first point) and cut off big y-values
     */
    x = qBound(spline.begin(), x, spline.end());
    qreal y = spline.getValue(x);
    return qBound(qreal(0.0), y, qreal(1.0));
}

template <typename _T_, typename _T2_> void KisCubicCurve::Data::updateTransfer(QVector<_T_> *transfer, bool &valid, _T2_ min, _T2_ max, int size)
{
    if (!valid || transfer->size() != size) {
        if (transfer->size() != size) {
            transfer->resize(size);
        }
        qreal end = 1.0 / (size - 1);
        for (int i = 0; i < size; ++i) {
            /* Direct uncached version */
            _T2_ val = value(i * end) * max;
            val = qBound(min, val, max);
            (*transfer)[i] = val;
        }
        valid = true;
    }
}

struct KisCubicCurve::Private
{
    QSharedDataPointer<Data> data;
};

KisCubicCurve::KisCubicCurve()
    : d(new Private)
{
    d->data = new Data;
    QPointF p;
    p.rx() = 0.0;
    p.ry() = 0.0;
    d->data->points.append(p);
    p.rx() = 1.0;
    p.ry() = 1.0;
    d->data->points.append(p);
}

KisCubicCurve::KisCubicCurve(const QList<QPointF> &points)
    : d(new Private)
{
    d->data = new Data;
    d->data->points = points;
    d->data->keepSorted();
}

KisCubicCurve::KisCubicCurve(const KisCubicCurve &curve)
    : d(new Private(*curve.d))
{
}

KisCubicCurve::~KisCubicCurve()
{
    delete d;
}

KisCubicCurve &KisCubicCurve::operator=(const KisCubicCurve &curve)
{
    *d = *curve.d;
    return *this;
}

bool KisCubicCurve::operator==(const KisCubicCurve &curve) const
{
    if (d->data == curve.d->data) {
        return true;
    }
    return d->data->points == curve.d->data->points;
}

qreal KisCubicCurve::value(qreal x) const
{
    return d->data->value(x);
}

QList<QPointF> KisCubicCurve::points() const
{
    return d->data->points;
}

void KisCubicCurve::setPoints(const QList<QPointF> &points)
{
    d->data.detach();
    d->data->points = points;
    d->data->invalidate();
}

int KisCubicCurve::setPoint(int idx, const QPointF &point)
{
    d->data.detach();
    d->data->points[idx] = point;
    d->data->keepSorted();
    d->data->invalidate();
    return idx;
}

int KisCubicCurve::addPoint(const QPointF &point)
{
    d->data.detach();
    d->data->points.append(point);
    d->data->keepSorted();
    d->data->invalidate();
    return d->data->points.indexOf(point);
}

void KisCubicCurve::removePoint(int idx)
{
    d->data.detach();
    d->data->points.removeAt(idx);
    d->data->invalidate();
}

const QString KisCubicCurve::toString() const
{
    QString sCurve;
    for (const QPointF &pair : qAsConst(d->data->points)) {
        sCurve += QString::number(pair.x());
        sCurve += QStringLiteral("/");
        sCurve += QString::number(pair.y());
        sCurve += QStringLiteral(";");
    }
    return sCurve;
}

void KisCubicCurve::fromString(const QString &string)
{
    const QStringList data = string.split(QLatin1Char(';'));

    QList<QPointF> points;
    for (const QString &pair : data) {
        if (pair.indexOf('/') > -1) {
            QPointF p;
            p.rx() = pair.section(QLatin1Char('/'), 0, 0).toDouble();
            p.ry() = pair.section(QLatin1Char('/'), 1, 1).toDouble();
            points.append(p);
        }
    }
    setPoints(points);
}

int KisCubicCurve::count() const
{
    return d->data->points.size();
}

QPointF KisCubicCurve::getPoint(int ix, int normalisedWidth, int normalisedHeight, bool invertHeight)
{
    QPointF p = d->data->points.at(ix);
    p.rx() *= normalisedWidth;
    p.ry() *= normalisedHeight;
    if (invertHeight) {
        p.ry() = normalisedHeight - p.y();
    }
    return p;
}
